# Giant intrinsic photoresponse in pristine graphene

**Authors:** Qiong Ma, Chun Hung Lui, Justin C. W. Song, Yuxuan Lin, Jian Feng, Kong, Yuan Cao, Thao H. Dinh, Nityan L. Nair, Wenjing Fang, Kenji Watanabe,, Takashi Taniguchi, Su-Yang Xu, Jing Kong, Tom\'as Palacios, Nuh Gedik,, Nathaniel M. Gabor, Pablo Jarillo-Herrero

arXiv: 1812.07111 · 2018-12-19

## TL;DR

This study uncovers a giant intrinsic photocurrent in pristine graphene at the charge neutrality point, driven by unique electron scattering kinematics, with potential applications in energy harvesting and understanding Dirac fluid dynamics.

## Contribution

It reveals a previously unobserved giant photocurrent in graphene linked to Dirac point physics and broken symmetries, advancing knowledge of electron dynamics in Dirac materials.

## Key findings

- Photocurrent appears only at charge neutrality point
- Photocurrent is suppressed at non-zero charge densities
- Enhanced photocurrent observed at graphene edges with sharp bends

## Abstract

When the Fermi level matches the Dirac point in graphene, the reduced charge screening can dramatically enhance electron-electron (e-e) scattering to produce a strongly interacting Dirac liquid. While the dominance of e-e scattering already leads to novel behaviors, such as electron hydrodynamic flow, further exotic phenomena have been predicted to arise specifically from the unique kinematics of e-e scattering in massless Dirac systems. Here, we use optoelectronic probes, which are highly sensitive to the kinematics of electron scattering, to uncover a giant intrinsic photocurrent response in pristine graphene. This photocurrent emerges exclusively at the charge neutrality point and vanishes abruptly at non-zero charge densities. Moreover, it is observed at places with broken reflection symmetry, and it is selectively enhanced at free graphene edges with sharp bends. Our findings reveal that the photocurrent relaxation is strongly suppressed by a drastic change of fast photocarrier kinematics in graphene when its Fermi level matches the Dirac point. The emergence of robust photocurrents in neutral Dirac materials promises new energy-harvesting functionalities and highlights intriguing electron dynamics in the optoelectronic response of Dirac fluids.

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Source: https://tomesphere.com/paper/1812.07111